We study a novel architecture and training procedure for locomotion tasks. A
high-frequency, low-level "spinal" network with access to proprioceptive
sensors learns sensorimotor primitives by training on simple tasks. This
pre-trained module is fixed and connected to a low-frequency, high-level
"cortical" network, with access to all sensors, which drives behavior by
modulating the inputs to the spinal network. Where a monolithic end-to-end
architecture fails completely, learning with a pre-trained spinal module
succeeds at multiple high-level tasks, and enables the effective exploration
required to learn from sparse rewards. We test our proposed architecture on
three simulated bodies: a 16-dimensional swimming snake, a 20-dimensional
quadruped, and a 54-dimensional humanoid. Our results are illustrated in the
accompanying video at https://youtu.be/sboPYvhpraQComment: Supplemental video available at https://youtu.be/sboPYvhpra
